Refrigerant handling apparatus employing roots type compressor

ABSTRACT

In an air-conditioning or refrigeration system, the expansive energy of the refrigerant itself is utilized to force some of the vapor formed in the throttling process into a closed volume chamber or well pocket of a Roots type compressor, one of the components of the system, facilitating a reduction in the required inlet volume and power of the compressor for a given cooling effect.

United States Patent [191 Weatherston Y REFRIGERANT HANDLING APPARATUS EMPLOYING ROOTS TYPE COMPRESSOR [4 1 May 7,1974

Primary Examiner-Meyer Perlin Attorney, Agent, or Firm-Allen J. Jaffe [57] ABSTRACT In an air-conditioning or refrigeration system, the expansive energy of the'refrigerant itself is utilized to force some of the vapor formed in the throttling process into a closed volume chamber or well pocket of a Roots type compressor, one of the components of the system, facilitating 'a reduction in the required inlet volume and power of the compressor for a given cooling effect.

-1 Claim, 1 Drawing Figure CONDENSER i MIB F n 2 I0 ROOTS TYPE 28 28' 9 COMPRESSOR 32 UPSTREAM 35 0 c? THROTTLE /25 34 I u &

FLASH. CHAMBER "=3 38 DOWNSTREAM 36 THROTTLE EVAPORATOR mimmm 1 m4 V $808,835

CONDENSER F I MIB 1- n v l0 ROOTS TYPE 28 28 29 COMPRESSOR 32 UPSTREAM 1-. 35 Q I THROTTLE H25 34 I3 14 FLASH I 2| 38 CHAMBER 1? 3a DOWNSTREAM 26 36 THROTTLE v 22 'EVAPORATORI REFRIGERANT HANDLING APPARATUS EMPLOYING ROOTS TYPE COMPRESSOR BACKGROUND OF THE INVENTION In some compression air-conditioning or refrigeration systems a throttling device is located in the refrigerant conduit between the condenser and expander for dropping the refrigerant pressure from the condenser pressure to the evaporator pressure preferably in at least two steps for better control. Such throttling device expands the liquid refrigerant to a low temperature liquid and vapor mixture, typically 30 percent vapor, which enters the evaporator wherein the remaining liquid refrigerant absorbs heat and is vaporized. The vapor entering the evaporator does not materially contribute to the cooling which occurs there, but since it must pass through the compressor this vapor constitutes about 30 percent of the total inlet flow volume and work requirement of the compressor.

SUMMARY OF THE INVENTION The foregoing disadvantage, as well as others, are overcome according to the present invention which provides refrigerant handling apparatus employing a Roots type compressor wherein the inlet to this compressor is not burdened to handle a significant amount of the vapor existing prior to the evaporator. In accordance with the present invention, refrigerant vapor produced as the result of at least a two step reduction in pressure and having a pressure intermediate the inlet and outlet pressures of the compressor is delivered directly in the closed volume chambers or well pockets of the compressor formed by its rotary coacting multilobed impellers, thereby increasing the amount of vapor compressed without affecting the work requirement of the compressor.

Basically, then, the present invention provides apparatus handling a vaporizable refrigerant and including in series an evaporator,- a Roots type compressor having a low pressure inlet, a high pressure outlet and a closed volume chamber intermediate said inlet and outlet, upstream throttling means for dropping the pressure of the refrigerant from condenser pressure, downstream-throttling means for dropping the pressure of the refrigerant to evaporator pressure, a flash chamber intermediate the two throttles in which the refrigerant vaporizes at a pressure intermediate the condenser and evaporator pressures, and a conduit feeding the separated vapor at such intermediate pressure into said closed volume chamber of the compressor.

For a fuller understanding of the present invention reference is made to the following detailed description of the same taken in conjunction with the accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWING The single FIGURE of the drawing depicts schematically apparatus providing a refrigeration cycle embodying the concept of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT In the accompanying drawing, the numeral represents generally a Roots type compressor including a housing 11 defining a working compartment 12 in which a pair of rotary coacting multilobed impellers 13 and 14 is arranged. Housing 11 has a low pressure inlet 15 and a high pressure outlet 16.

Outlet 16 is shown as communicatively connected via conduit 18 to a condenser 19 of any suitable construction. The outlet of this condenser is shown as communicatively connected via conduit 20 to the upper end of an enlarged flash chamber 21, the lower end of which is shown as communicatively connected via conduit 22 to the inlet of an evaporator 23 of any suitable con-' struction. The outlet of this evaporator is shown as communicatively connected via conduit 24 to compressor inlet 15.

In thisseries arrangement of components to produce a refrigeration cycle, there is also provided an upstream throttle 25, specifically in the form of a restricted orifice arranged at the juncture of conduit 20 with flash chamber 21. A downstream throttle 26, also in the form of a restricted orifice, is shown arranged at the juncture of conduit 22 with flash chamber 21. Other forms of throttling devices may be employed, the simple restricted orifices shown being schematic and illustrative.

Adverting again'to the Roots type compressor 10, the housing 11 thereof is preferably formed to provide a pair of ledges 28 and 29 adjacent outlet 16 in each of which is provided a feedback passage 28' or 29' for directing a fluid jetat high outlet pressure against a lobe of the corresponding impeller 13 or 14, in the manner and for the purpose disclosed in US. Pat. No. 3,531,227. Adjacent inlet 15, housing 11 is shown as formed to provide a pair of ledges 30 and 31 as definitive extensions of working chamber 12. Left impeller 13 is shown as arranged'to rotate in a clockwise direction about a central axis. Right impeller 14 is shown as arranged to rotate in a counterclockwise direction about a central axis. Any suitable means, known to those skilled in the art, may be provided to effect the described rotation and coaction of impellers l3 and 14.

While each of the impellers l3 and 14 is shown as having three lobes, this is for illustrative purposes only, and they may have more lobes. It will .be noted that the salients of two adjacent lobes on each of the impellers l3 and 14 can have concurrently a'substantially sealed wiping contact on the circular wall portion of the working compartment 12 partially surrounding each impeller. Such concurrent contact between the two lobes provides jointly with the wall of the working compartment 12 a closed volume chamber or well pocket, indicated at 32 for leftimpeller 13 and at 33 for right impeller 14. This is a moving chamber or pocket, specifically of constant volume. It is first closed when the trailing one of an adjacent pair of lobes sealingly contacts the edge of shelf 30 or 31, and first opened when the other orleading one of such pair uncovers feedback passage 28' or 29.

An important feature of the present invention is to conduct refrigerant vapor which has separated from liquid in flash chamber 21, and which is at a pressure intermediate the pressures obtaining in the compressor inlet 15 and outlet 16, into the closed volume or well pockets 32 and 33. This is shown as achieved by a conduit 34 communicatively connected at one end to the upper portion of flash chamber 21 and at its other end to an inlet 35 in the wall of housing and leading to chamber 32, and a branch conduit 36 communicatively connected at one end to conduit 34 and at its other end to an inlet 38 in the wall of housing and leading to chamber 33.

Refrigerant in conduit 20 is essentially liquid, as it is also in conduit 22. However, refrigerant at the pressure obtaining intermediate throttling orifices '25 and 26 causes some refrigerant to vaporize at this intermediate pressure, collecting adjacent the upper end of flash chamber 21 above the level of liquid refrigerant maintained therein. It is this refrigerant vapor at such intermediate pressure level, above that obtaining at compressor inlet but below that obtaining at compressor outlet 16, which will cause such vapor to flow into and fill chambers or pockets 32 and 33.

Since the refrigerant in conduit 22 admitted into evaporator 23 is essentially all in liquid form, it is almost all available for vaporization to produce a cooling effect, so that the vapor reaching compressor inlet 15 has been efficiently utilized.

With the arrangement of components as described herein part of the refrigerant that would normally enter the compressor inlet in a conventional refrigeration system is diverted into the well pockets 32, 33 of the compressor at 35 and 38. Since the power requirement of a Roots type compressor for a given size and speed is only a function of the pressure difference between the discharge and inlet, the vapor takeoff of the refrigerant in flash chamber 21 to pockets 32 and 33 does not in any way increase the loading on or work requirements of the compressor. Hence, contrasted to a conventional system for a given cooling capacity and refrigerant flow rate the size and power requirements of the compressor according to the present invention may be reduced.

Although a preferred embodiment of the present invention has been described, changes will occur to those skilled in the art; therefore, it is intended that the scope of the present invention is to be limited only by the scope of the appended claims.

I claim:

1. In apparatus handling a vaporizable refrigerant and including in series an evaporator, a Roots type compressor having a low pressure inlet, a high pressure outlet, and a closed constant volume chamber intermediate said inlet and outlet, upstream throttling means for dropping the pressure of the refrigerant from condenser pressure, and downstream throttling means for dropping the pressure of the refrigerant to evaporator pressure, wherein the improvement comprises flash chamber means arranged between said upstream and downstream throttling means in which refrigerant vaporizes at a pressure intermediate said condenser and evaporator pressures, and conduit means establishing communication between said flash chamber means and said closed volume chamber for introducing refrigerant vapor at such intermediate pressure into said closed volume chamber. 

1. In apparatus handling a vaporizable refrigerant and including in series an evaporator, a Roots type compressor having a low pressure inlet, a high pressure outlet, and a closed constant volume chamber intermediate said inlet and outlet, upstream throttling means for dropping the pressure of the refrigerant from condenser pressure, and downstream throttling means for dropping the pressure of the refrigerant to evaporator pressure, wherein the improvement comprises flash chamber means arranged between said upstream and downstream throttling means in which refrigerant vaporizes at a pressure intermediate said condenser and evaporator pressures, and conduit means establishing communication between said flash chamber means and said closed volume chamber for introducing refrigerant vapor at such intermediate pressure into said closed volume chamber. 